Difference between revisions of "Hemochromatosis"

From Bioinformatikpedia
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[[File:Hfe_mutation.png|frame|HFE-Protein(blue) in complex with beta-microglobulin(cyan). The cystein at position 282 is highlighted in red and its disulfide interaction partner in orange. Source: PDB ID 1A6Z, visualized with PyMOL]]
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[[File:Hfe_mutation_small.png|frame|HFE-Protein(blue) in complex with beta-microglobulin(cyan). The cystein at position 282 is highlighted in red and its disulfide interaction partner in orange. Source: PDB ID 1A6Z, visualized with PyMOL]]
   
   
'''Hemochromatosis''' is a hereditary disorder that leads to an increased intestinal iron uptake from food. The excess iron is stored in the parenchymal cells of organs and tissues and thus disrupts their normal function. There are various genotypes that can lead to hemochromatosis. The most common form of the disease is caused by a point mutation in the HFE gene. HFE stands for High FErrum.
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'''Hemochromatosis''' is a hereditary disorder that leads to an increased intestinal iron uptake from food. The excess iron is stored in the parenchymal cells of organs and tissues and thus disrupts their normal function. There are various genotypes that can lead to hemochromatosis. The most common form of the disease is caused by a point mutation in the '''HFE''' gene. '''HFE''' stands for '''H'''igh '''FE'''rrum.
   
 
== Phenotype ==
 
== Phenotype ==
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Iron is the 4th most common element in the world. In nature, it normally occurs in its oxidized form Fe<sup>3+</sup>, that is unsoluble in water. That is, why iron in humans mostly occurs complexed. Free, water soluble iron ions that appear in the reduced form Fe<sup>2+</sup>, are toxic because they can react with H<sub>2</sub>O<sub>2</sub> to produce highly reactive hydroxy radicals that damage membranes, proteins and nucleic acids.
 
Iron is the 4th most common element in the world. In nature, it normally occurs in its oxidized form Fe<sup>3+</sup>, that is unsoluble in water. That is, why iron in humans mostly occurs complexed. Free, water soluble iron ions that appear in the reduced form Fe<sup>2+</sup>, are toxic because they can react with H<sub>2</sub>O<sub>2</sub> to produce highly reactive hydroxy radicals that damage membranes, proteins and nucleic acids.
 
Nevertheless, iron plays a crucial role in the human body. It binds to hemoglobin as a cofactor and enables oxygen transport. The total amount of iron in the body ranges from 3000mg-5000mg, whereby around 65% are bound to hemoglobin and the rest is either bound to other proteins as cofactor or stored in cells as reservoir.
 
Nevertheless, iron plays a crucial role in the human body. It binds to hemoglobin as a cofactor and enables oxygen transport. The total amount of iron in the body ranges from 3000mg-5000mg, whereby around 65% are bound to hemoglobin and the rest is either bound to other proteins as cofactor or stored in cells as reservoir.
Iron is only removed from the body through blood loss, sweating or shedding of mucosal or skin cells. This amounts to an average of 1mg per day for men and 1.5-2mg per day for women. Women lose more iron, because they regularly loose blood due to menstruation. The amount of iron in a healthy human is kept constant by the regulatory mechanisms of the body. This means, that only as much, as the organism looses, is taken up.
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Iron is only removed from the body through blood loss, sweating or shedding of mucosal or skin cells. This amounts to an average of 1 mg per day for men and 1.5-2 mg per day for women. Women lose more iron, because they regularly loose blood due to menstruation. The amount of iron in a healthy human is kept constant by the regulatory mechanisms of the body. This means that only as much, as the organism looses, is taken up.
   
 
[[File:Small_intestine_anatomy.jpg|frame|Detailed illustration of the anatomy of the small intestine where iron resorption takes place. Source: http://www.edoctoronline.com/media/19/photos_88EB3125-5618-45A8-BA5D-2834A502C2E1.jpg]]
 
[[File:Small_intestine_anatomy.jpg|frame|Detailed illustration of the anatomy of the small intestine where iron resorption takes place. Source: http://www.edoctoronline.com/media/19/photos_88EB3125-5618-45A8-BA5D-2834A502C2E1.jpg]]
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Iron is only able to enter the human body in the small intestine. The main part(~40%) is resorbed in the duodenum and afterwards the resorption linearly decreases.
 
  +
Iron is only able to enter the human body in the small intestine. The main part is taken up in the duodenum and the resorbtion decreases linearly towards the ileum(end of the small intestine).
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The iron in the lumen of the small intestine is transported into the enterocytes through the '''D'''ivalent '''M'''etal '''T'''ransporter 1(DMT-1)
   
 
 

Revision as of 21:36, 28 April 2013

Work in progress!


File:Hfe mutation small.png
HFE-Protein(blue) in complex with beta-microglobulin(cyan). The cystein at position 282 is highlighted in red and its disulfide interaction partner in orange. Source: PDB ID 1A6Z, visualized with PyMOL


Hemochromatosis is a hereditary disorder that leads to an increased intestinal iron uptake from food. The excess iron is stored in the parenchymal cells of organs and tissues and thus disrupts their normal function. There are various genotypes that can lead to hemochromatosis. The most common form of the disease is caused by a point mutation in the HFE gene. HFE stands for High FErrum.

Phenotype

Clinical symptoms include:

  • tiredness
  • joint and bone pain
  • destructive arthritis
  • liver fibrosis and cirrhosis, increased risk to develop hepatocellular carcinoma
  • Glucose intolerance and insulin resistance due to damages in the pancreas (diabetes mellitus).
  • Gonadal dysfunction, hypogonadism and decreased libido.
  • heart failure, arrhythmias or pericarditisheart failure
  • grey or dark cutaneous (skin) pigmentation


The hemocromatosis phenotype and its harmfulness varies in patients with the same disease causing mutation. Symptoms are caused by a high, toxic iron accumulation in parenchymal cells of important organs, like the heart, the liver or the endocrine glands. The disease is usually diagnosed in middle aged patients, because the iron accumulates over time and severe symptoms are not immidiately apparent. Depending on which organs are affected most by the increased iron uptake, the symptoms range from simple biochemical abnormalities to severe diseases such as heart failure and liver cirrhosis.

The individual phenotype varies that much, because the genetic background only gives a predisposition to hemochromatosis. Human and environmental factors play an important role as well. In general, male indiviuals that have the genetic predisposition, have a higher probability of developing hemochromatosis, supposedly because females have an overall higher iron loss due to menstruation.

Cross references

see also the description in

http://en.wikipedia.org/wiki/Hereditary_haemochromatosis
http://omim.org/entry/235200
http://www.gastrojournal.org/article/S0016-5085%2810%2900872-3/fulltext


Biochemical disease mechanism

The role of iron in the body

Iron is the 4th most common element in the world. In nature, it normally occurs in its oxidized form Fe3+, that is unsoluble in water. That is, why iron in humans mostly occurs complexed. Free, water soluble iron ions that appear in the reduced form Fe2+, are toxic because they can react with H2O2 to produce highly reactive hydroxy radicals that damage membranes, proteins and nucleic acids. Nevertheless, iron plays a crucial role in the human body. It binds to hemoglobin as a cofactor and enables oxygen transport. The total amount of iron in the body ranges from 3000mg-5000mg, whereby around 65% are bound to hemoglobin and the rest is either bound to other proteins as cofactor or stored in cells as reservoir. Iron is only removed from the body through blood loss, sweating or shedding of mucosal or skin cells. This amounts to an average of 1 mg per day for men and 1.5-2 mg per day for women. Women lose more iron, because they regularly loose blood due to menstruation. The amount of iron in a healthy human is kept constant by the regulatory mechanisms of the body. This means that only as much, as the organism looses, is taken up.

Detailed illustration of the anatomy of the small intestine where iron resorption takes place. Source: http://www.edoctoronline.com/media/19/photos_88EB3125-5618-45A8-BA5D-2834A502C2E1.jpg

Iron is only able to enter the human body in the small intestine. The main part is taken up in the duodenum and the resorbtion decreases linearly towards the ileum(end of the small intestine). The iron in the lumen of the small intestine is transported into the enterocytes through the Divalent Metal Transporter 1(DMT-1)




Illustration of the iron uptake into the blood and its regulation. Source: http://ars.els-cdn.com/content/image/1-s2.0-S0021997512001570-gr1.jpg


Although there are some theories about the exact biochemical disease mechanism, it is not resolved yet.

The basis for hemocromatosis is a hepcidin deficiency. Hepcidin is a protein that is responsible for the downregulation of iron entry into the bloodstream. Patients do not suffer from a perturbance of the iron metabolism, which works normal, but from an increased iron uptake into the blood.


Genetics and Inheritance

There are several different types of hemochromatosis. Each type is connected to defects in the iron uptake regulation through hepcdin. The most common and less severe type is caused by a mutation in the HFE gene on chromosome 6. The other types are rare and based on a mutations in the TfR2 gene or, in the case of juvenile hemochromatisis, mutations in the HJV or HAMP (Hepcidin) gene. Mutations in the FPN(Ferroportin) gene can also result in hemachromatosis like symptoms, but it is often termed ferroportin disease. The mutations leads to a hepcidin resistance and thus to an iron hyperabsorbtion from the diet, although the hepcidin production is not impaired in this patients.

Homozygosity for one of the above mentioned mutations only results in a certain predisposition to hemochromatosis, but not all persons with this genetic background develop the disease. It depends on other influences on the iron metabolism, such as abusive drinking.


Characterisation of the various forms of hemochromatosis
form male/female age non-/caucasian
HFE male 40-50 years caucasian
TfR2 male or female 30-40 years caucasian or non-caucasian
HJV, HAMP male or female 15-20 years caucasian or non-caucasian
Ferroportin disease male or female 10-80 years caucasian or non-caucasian

Hemochromatosis is an autosomal recessive inherited disorder with reduced penetrance in female. The HFE C282Y mutation is a very common one with a homozygozity prevalence of 1:200 to 1:300 in white persons, why it is a polymorphism rather than a disease mutation. But among Asians, Hispanics or black persons it is much less common. Roughly 80% of northern European hemachromatosis patients are homozygous for HFE C282Y. A Celtic or Vikin ancester was probably the first person having the mutation. Since hemochromatisis does not infect reproduction, the mutation spread through populations. The C282Y allel has a frequency of 12.5% in Ireland and 0% in southern Europe, but the mean frequency among white individuals is 6%.

H63D is anothe HFE polymorphism with less geographic distribution and a higher prevalence of 14%, but it has nearly no penetrance. The S65C polymorphism is associated with high iron levels when it is inherited together with C282Y on one allele.

All the other non-HFE hemochromatosis types are spread throughout the world, independent of any race, but they are much rarer. In 50% of families with a case of juvenile hemachromatose has the G320V mutation in the HJV gene been detected.

This wiki entry focuses on the HFE C282Y mutation, because it is the most common reason for hemachromatosis in northern Europe.

HFE C282Y

The HFE gene is located on chromosome 6 on the short arm (p) in region 21.3 (6p21.3) and consists of 7 exons spanning 12 kb. It encodes for the HFE protein, which is a membrane protein similar to the MHC class I proteins and HFE wthuw associates with beta2-microglobulin. HFE binds to the transferrin receptor 2 (TfR2) and is thought to play a role in the pathway that senses the serum iron level (transferrin-bound and un-unbound) and regulates the expression of hepcidin.

A guanin to adenine transition at position 845 in the HFE gene lead to the C282Y substitiution in the protein sequence. This missense mutation affects a highly conserved cystein in the alpha-3 loop of the HFE protein that normally forms a disulfide bond in the unmutated protein.(see picture above) The tyrosine in the mutated protein therefore disrupts the structure and prevents the binding of HFE to beta-2-microglobulin.

Cross references

see also the description in

http://omim.org/entry/613609 http://omim.org/entry/235200
http://www.genecards.org/cgi-bin/carddisp.pl?gene=HFE&search=HFE&suff=txt

Mutations

Each of the above mentioned different types of hemochromatosis is caused by a different mutation.

HFE: C282Y, H63D
TfR2: Y250X (nonsense mutation, it truncates TfR2 at amoino acid 250)
HJV: G320V
HAMP: several, no specific
FPN: C326S and C326Y

Reference sequence

protein sequence:

>gi|1890180|emb|CAB07442.1| HFE [Homo sapiens]
MGPRARPALLLLMLLQTAVLQGRLLRSHSLHYLFMGASEQDLGLSLFEALGYVDDQLFVFYDHESRRVEP
RTPWVSSRISSQMWLQLSQSLKGWDHMFTVDFWTIMENHNHSKESHTLQVILGCEMQEDNSTEGYWKYGY
DGQDHLEFCPDTLDWRAAEPRAWPTKLEWERHKIRARQNRAYLERDCPAQLQQLLELGRGVLDQQVPPLV
KVTHHVTSSVTTLRCRALNYYPQNITMKWLKDKQPMDAKEFEPKDVLPNGDGTYQGWITLAVPPGEEQRY
TCQVEHPGLDQPLIVIWEPSPSGTLVIGVISGIAVFVVILFIGILFIILRKRQGSRGAMGHYVLAERE

http://www.ncbi.nlm.nih.gov/protein/1890180?report=fasta


Diagnosis and Treatment

Algorithm for the diagnosis of hemochromatosis. Source: http://www.gastrojournal.org/article/S0016-5085%2810%2900872-3/fulltext

Hemochromatosis is diagnosed in patients with an unnormal high transferrin saturation (TS) and, in later stages, increased serum ferritin levels. The transferrin saturation denotes the concentration of free iron in proportion to the concentration of transferin in the blood serum. However, the diagnosis should always be supported by a gene test for HFE C282Y homyozygocity. Inflammation, metabolic disorders, diabetes mellitus, alcohol abuse and liver cell necrosis can also lead to an increased serum ferritin level. On the other hand, a finding of normal serum ferritin level alsways excludes hemochromatosis.

Since iron can only be removed from the system by blood loss, the only possible treatment is phlebotomy (bloodletting). It is aimed to reduce the iron content in the body. The first step of the iron-depletion treatment is to induce a slightly iron-deficient state in the body. Therfore, 400-500 ml blood are removed weekly. After 1 to 2 years a serum ferrition level of 20-50 μg/l is reached. In the long term, a maintenance therapy with two to four phlebotomies a year is then enough to keep the serum ferritin level between 50-100 μg/l.

A low iron diet can help. The life expectancy of dignosed and treated hemochromatosis patients withour complications is comparable to that of the normal population. But early diagnosis and initation of therapy increase survival time.


Resources

The entry is based on several resources:

http://www.gastrojournal.org/article/S0016-5085%2810%2900872-3/fulltext http://omim.org/entry/613609 http://omim.org/entry/235200
http://en.wikipedia.org/wiki/Hereditary_haemochromatosis http://www.genecards.org/cgi-bin/carddisp.pl?gene=HFE&search=HFE&suff=txt